Nerve impulse conduction
62,302 views
26 slides
Dec 30, 2014
Slide 1 of 26
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
About This Presentation
Nerve impulse conduction
Slide Content
NERVE IMPULSE
CONDUCTION
SUBMITTED BY:-
Praveen kumar
Dept. Of Biochemistry
Kurukshetra University
Roll no - 17
CONDUCTION
SUBMITTED BY:-
Praveen kumar
Dept. Of Biochemistry
Kurukshetra University
Roll no - 17
CONTENTS
1.Structure of a nerve cell
2. Resting Potential
3. Action Potential
(a) Formation of an action
potential
4. Propagation of Action
Potentials as an Impulse
(b) Saltatory conduction
5. Neurotransmission: Jumping
the Synaptic Cleft
1.Structure of a nerve cell
2. Resting Potential
3. Action Potential
(a) Formation of an action
potential
4. Propagation of Action
Potentials as an Impulse
(b) Saltatory conduction
5. Neurotransmission: Jumping
the Synaptic Cleft
TYPICAL NEURON
Neuron
•Dendrite - conducts “signal” toward the cell body -- [input zone]
–often short, numerous & highly branched
–signal comes from sensory cell or neighboring neuron
•Axon - usually a single fiber -- [conducting zone]
–conducts signal away from cell body to another neuron or effector cell
•Axon Ending
–a cluster of branches (100’s to 1000’s)
–each with a bulblike synaptic knob
–relays signal to next neuron / effector cell
•Dendrite - conducts “signal” toward the cell body -- [input zone]
–often short, numerous & highly branched
–signal comes from sensory cell or neighboring neuron
•Axon - usually a single fiber -- [conducting zone]
–conducts signal away from cell body to another neuron or effector cell
•Axon Ending
–a cluster of branches (100’s to 1000’s)
–each with a bulblike synaptic knob
–relays signal to next neuron / effector cell
Typical neuron
RESTING POTENTIAL
Resting potential may be defined as the
difference in voltage between the inside and
outside of the cell as measured across the
cell membrane.
•When a neuron is not being stimulated, it
maintains a resting potential
Ranges from –40 to –90 millivolts (mV)
Average about –70 mV
Resting potential may be defined as the
difference in voltage between the inside and
outside of the cell as measured across the
cell membrane.
•When a neuron is not being stimulated, it
maintains a resting potential
Ranges from –40 to –90 millivolts (mV)
Average about –70 mV
RESTING POTENTIAL
•Two major forces act on ions in establishing
the resting membrane potential
1.Electrical potential produced by unequal
distribution of charges
2.Concentration gradient produced by
unequal concentrations of molecules
from one side of the membrane to the
other
•Two major forces act on ions in establishing
the resting membrane potential
1.Electrical potential produced by unequal
distribution of charges
2.Concentration gradient produced by
unequal concentrations of molecules
from one side of the membrane to the
other
RESTING POTENTIAL
•Sodium–potassium pump creates significant
concentration gradient
•Concentration of K
+
is much higher inside the
cell
•Membrane not permeable to negative ions
•Leads to buildup of positive charges outside
and negative charges inside cell
•Attractive force to bring K
+
back inside cell
•Equilibrium potential – balance between
diffusional force and electrical force
8
•Sodium–potassium pump creates significant
concentration gradient
•Concentration of K
+
is much higher inside the
cell
•Membrane not permeable to negative ions
•Leads to buildup of positive charges outside
and negative charges inside cell
•Attractive force to bring K
+
back inside cell
•Equilibrium potential – balance between
diffusional force and electrical force
8
ACTION POTENTIAL
• Action potential may be defined as the entire series of
changes which contribute towards the changes in
membrane potential.
Action
potentials:-
–Result when depolarization reaches the threshold
potential (–55 mV)
–Depolarizations bring a neuron closer to the
threshold
–Hyperpolarizations move the neuron further from
the threshold
–Caused by voltage-gated ion channels
•Voltage-gated Na
+
channels
•Voltage-gated K
+
channels
• Action potential may be defined as the entire series of
changes which contribute towards the changes in
membrane potential.
Action
potentials:-
–Result when depolarization reaches the threshold
potential (–55 mV)
–Depolarizations bring a neuron closer to the
threshold
–Hyperpolarizations move the neuron further from
the threshold
–Caused by voltage-gated ion channels
•Voltage-gated Na
+
channels
•Voltage-gated K
+
channels
ACTION POTENTIAL
•Voltage-gated Na
+
channels
–Activation gate and inactivation gate
–At rest, activation gate closed, inactivation gate
open
–Transient influx of Na
+
causes the membrane to
depolarize
•Voltage-gated K
+
channels
–Single activation gate that is closed in the resting
state
–K
+
channel opens slowly
–Efflux of K
+
repolarizes the membrane
•Voltage-gated Na
+
channels
–Activation gate and inactivation gate
–At rest, activation gate closed, inactivation gate
open
–Transient influx of Na
+
causes the membrane to
depolarize
•Voltage-gated K
+
channels
–Single activation gate that is closed in the resting
state
–K
+
channel opens slowly
–Efflux of K
+
repolarizes the membrane
ACTION POTENTIAL
•The action potential has three phases
–Rising, falling, and undershoot
•Action potentials are always separate, all-or-
none events with the same amplitude
•Do not add up or interfere with each other
•Intensity of a stimulus is coded by the
frequency, not amplitude, of action potentials
11
•The action potential has three phases
–Rising, falling, and undershoot
•Action potentials are always separate, all-or-
none events with the same amplitude
•Do not add up or interfere with each other
•Intensity of a stimulus is coded by the
frequency, not amplitude, of action potentials
11
12
GENRATION OF ACTION
POTENTIAL
POTENTIAL
PROPAGATION OF ACTION
POTENTIAL
•Propagation of action potentials
–Each action potential, in its rising phase,
reflects a reversal in membrane polarity
–Positive charges due to influx of Na
+
can
depolarize the adjacent region to threshold
–And so the next region produces its own
action potential
–Meanwhile, the previous region repolarizes
back to the resting membrane potential
•Signal does not go back toward cell
body
POTENTIAL
•Propagation of action potentials
–Each action potential, in its rising phase,
reflects a reversal in membrane polarity
–Positive charges due to influx of Na
+
can
depolarize the adjacent region to threshold
–And so the next region produces its own
action potential
–Meanwhile, the previous region repolarizes
back to the resting membrane potential
•Signal does not go back toward cell
body
15
PROPAGATION OF ACTION
POTENTIAL
•Two ways to increase velocity of conduction
–Axon has a large diameter
•Less resistance to current flow
•Found primarily in invertebrates
–Axon is myelinated
•Action potential is only produced at the
nodes of Ranvier
•Impulse jumps from node to node
•Saltatory conduction
16
POTENTIAL
•Two ways to increase velocity of conduction
–Axon has a large diameter
•Less resistance to current flow
•Found primarily in invertebrates
–Axon is myelinated
•Action potential is only produced at the
nodes of Ranvier
•Impulse jumps from node to node
•Saltatory conduction
16
17
SALTATORY CONDUCTION
SALTATORY CONDUCTION
NEUROTRANSMISSION
•Electrical [no synapse]
–common in heart & digestive tract - maintains steady,
rhythmic contraction
–All cells in effector contain receptor proteins for
neurotransmitters
•Chemical - skeletal muscles & CNS
–presence of gap (SYNAPTIC CLEFT) which prevents action
potential from moving directly to receiving neuron
–ACTION POTENTIAL (electrical) converted to CHEMICAL
SIGNAL at synapse (molecules of neurotransmitter) then
generate ACTION POTENTIAL (electrical) in receiving
neuron
•Electrical [no synapse]
–common in heart & digestive tract - maintains steady,
rhythmic contraction
–All cells in effector contain receptor proteins for
neurotransmitters
•Chemical - skeletal muscles & CNS
–presence of gap (SYNAPTIC CLEFT) which prevents action
potential from moving directly to receiving neuron
–ACTION POTENTIAL (electrical) converted to CHEMICAL
SIGNAL at synapse (molecules of neurotransmitter) then
generate ACTION POTENTIAL (electrical) in receiving
neuron
Overview of Transmission of Nerve Impulse
•Action potential
® synaptic knob
® opening of Ca
+
channels
®neurotransmitter vesicles fuse with
membrane
®release of neurotransmitter into synaptic cleft
®binding of neurotransmitter to protein receptor
molecules on receiving neuron membrane
®opening of ion channels
®triggering of new action potential.
•Action potential
® synaptic knob
® opening of Ca
+
channels
®neurotransmitter vesicles fuse with
membrane
®release of neurotransmitter into synaptic cleft
®binding of neurotransmitter to protein receptor
molecules on receiving neuron membrane
®opening of ion channels
®triggering of new action potential.
NEUROTRANSMISSION
•Presynaptic neuron
•Vesicles
•[Calcium channels]
•Synaptic cleft
•Postsynaptic neuron
•Neurotransmitter receptor
•Presynaptic neuron
•Vesicles
•[Calcium channels]
•Synaptic cleft
•Postsynaptic neuron
•Neurotransmitter receptor
NEUROTRANSMISSION
•Action potential
® synaptic knob
® opening of Ca
+
channels
®neurotransmitter
vesicles fuse with
membrane
®release of
neurotransmitter into
synaptic cleft
Ca
2+
•Action potential
® synaptic knob
® opening of Ca
+
channels
®neurotransmitter
vesicles fuse with
membrane
®release of
neurotransmitter into
synaptic cleft
Ca
2+
NEUROTRANSMISSION
•Action potential
®neurotransmitter
vesicles fuse with
membrane
®release of
neurotransmitter into
synaptic cleft
•Action potential
®neurotransmitter
vesicles fuse with
membrane
®release of
neurotransmitter into
synaptic cleft
NEUROTRANSMISSION
•Action potential
®binding of
neurotransmitter to
protein receptor
molecules on receiving
neuron membrane
®opening of sodium
channels
®triggering of new
action potential
•Action potential
®binding of
neurotransmitter to
protein receptor
molecules on receiving
neuron membrane
®opening of sodium
channels
®triggering of new
action potential
NEUROTRANSMITTERS
•Amino acid derived Neurotransmitters
–Derived from amino acid tyrosine
norepinephrine, epinephrine
•Amine Neurotransmitters
–acetylcholine, histamine, serotonin
•Amino Acids
–aspartic acid, GABA, glutamic acid, glycine
•Polypeptides
–Include many which also function as hormones
–endorphins
•Amino acid derived Neurotransmitters
–Derived from amino acid tyrosine
norepinephrine, epinephrine
•Amine Neurotransmitters
–acetylcholine, histamine, serotonin
•Amino Acids
–aspartic acid, GABA, glutamic acid, glycine
•Polypeptides
–Include many which also function as hormones
–endorphins
References
•Cell and Molecular Biology by Gerald Karp
•Cell and Molecular Biology,8
th
ed.E.D.P.
Robertis and E.M.F. De Robertis
•Net source:- www.freeman.karp.in
•For any query contact-9896543665
•Cell and Molecular Biology by Gerald Karp
•Cell and Molecular Biology,8
th
ed.E.D.P.
Robertis and E.M.F. De Robertis
•Net source:- www.freeman.karp.in
•For any query contact-9896543665
THANKS
End of Presentation
That’s all
folks
End of Presentation
That’s all
folks
Tags
Categories
GeneralDownload
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 62,302
- Slides 26
- Favorites 111
- Age 3991 days
Related Slideshows
22
Pray For The Peace Of Jerusalem and You Will Prosper
RodolfoMoralesMarcuc
32 views
26
Don_t_Waste_Your_Life_God.....powerpoint
chalobrido8
35 views
31
VILLASUR_FACTORS_TO_CONSIDER_IN_PLATING_SALAD_10-13.pdf
JaiJai148317
32 views
14
Fertility awareness methods for women in the society
Isaiah47
30 views
35
Chapter 5 Arithmetic Functions Computer Organisation and Architecture
RitikSharma297999
29 views
5
syakira bhasa inggris (1) (1).pptx.......
ourcommunity56
30 views